Different Patterns in Daytime and Nighttime Thermal Effects of Urbanization in  Beijing-Tianjin-Hebei Urban Agglomeration

Zhao, Guosong; Dong, Jinwei; Liu, Jiyuan; Zhai, Jun; Cui, Yaoping; He, Tao; Xiao, Xiangming

doi:10.3390/rs9020121

Cited by 37 publications

(23 citation statements)

References 73 publications

(109 reference statements)

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“…Although there is no doubt that the form and expansion of urban landscape directly increases the threats of UHIs, the quantitative spatiotemporal variations of land surface temperature (LST) under urban landscape transformation are diverse [3][4][5][6]. This diversification could be caused by differences in seasons, hours, climate zones, and urbanization types [7][8][9][10]. Thus, the relationship between landscape pattern and LST is not consistent among various research conditions.…”

Section: Introductionmentioning

confidence: 94%

Diversification of Land Surface Temperature Change under Urban Landscape Renewal: A Case Study in the Main City of Shenzhen, China

2017

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Abstract:Unprecedented rapid urbanization in China during the past several decades has been accompanied by extensive urban landscape renewal, which has increased the urban thermal environmental risk. However, landscape change is a sufficient but not necessary condition for land surface temperature (LST) variation. Many studies have merely highlighted the correlation between landscape pattern and LST, while neglecting to comprehensively present the spatiotemporal diversification of LST change under urban landscape renewal. Taking the main city of Shenzhen as a case study area, this study tracked the landscape renewal and LST variation for the period 1987-2015 using 49 Landsat images. A decision tree algorithm suitable for fast landscape type interpretation was developed to map the landscape renewal. Analytical tools that identified hot-cold spots, the gravity center, and transect of LST movement were adopted to identify LST changes. The results showed that the spatial variation of LST was not completely consistent with landscape change. The transformation from Green landscape to Grey landscape usually increased the LST within a median of 0.2 • C, while the reverse transformation did not obviously decrease the LST (the median was nearly 0 • C). The median of LST change from Blue landscape to Grey landscape was 1.0 • C, corresponding to 0.5 • C in the reverse transformation. The imbalance of LST change between the loss and gain of Green or Blue landscape indicates the importance of protecting natural space, where the benefits in terms of temperature mitigation cannot be completely substituted by reverse transformation.

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Section: Introductionmentioning

confidence: 94%

Diversification of Land Surface Temperature Change under Urban Landscape Renewal: A Case Study in the Main City of Shenzhen, China

2017

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“…Other Australian State capitals including Sydney, Melbourne and Adelaide are involved with the Urban Climates Project identifying effects of the UHI for integration into planning and design guidelines [63]. However, current global UHI methodologies frequently provide singular metropolitan temperature comparison values for cities, which are inappropriate for assessing land-cover temperature change relationships at the intra-urban scale [30,[52][53][54][55]. Such limitations in current UHI measurement approaches prevent effective UHI mitigation and future sustainable rezoning policy formulations required at the sub-metropolitan level, as defined by the State, Planning Commission and Local Government strategies [62].…”

Section: Study Areamentioning

confidence: 99%

“…Cross-sectional studies either ignore the temporal component of urbanisation on LST [49,50] or assume a consistent urban area over the study period [5,48,51]. Longitudinal studies classify land cover over multiple periods but often disregard valuable spatial information through comparison of global temperature indices (e.g., the Urban Heat Island Intensity (UHII)) across years and do not quantify changes in land cover that are associated with temperature change [30,[52][53][54][55]. Transformation of land during urbanisation encompasses a broad range of changes within metropolitan regions which are frequently excluded from temperature analysis, and this needs consideration to address the aforementioned limitations.…”

Section: Introductionmentioning

confidence: 99%

Urbanisation-Induced Land Cover Temperature Dynamics for Sustainable Future Urban Heat Island Mitigation

et al. 2017

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Abstract:Urban land cover is one of the fastest global growing land cover types which permanently alters land surface properties and atmospheric interactions, often initiating an urban heat island effect. Urbanisation comprises a number of land cover changes within metropolitan regions. However, these complexities have been somewhat neglected in temperature analysis studies of the urban heat island effect, whereby over-simplification ignores the heterogeneity of urban surfaces and associated land surface temperature dynamics. Accurate spatial information pertaining to these land cover change-temperature relationships across space is essential for policy integration regarding future sustainable city planning to mitigate urban heat impacts. Through a multi-sensor approach, this research disentangles the complex spatial heterogeneous variations between changes in land cover (Landsat data) and land surface temperature (MODIS data), to understand the urban heat island effect dynamics in greater detail for appropriate policy integration. The application area is the rapidly expanding Perth Metropolitan Region (PMR) in Western Australia (WA). Results indicate that land cover change from forest to urban is associated with the greatest annual daytime and nighttime temperature change of 0.40 • C and 0.88 • C respectively. Conversely, change from grassland to urban minimises temperature change at 0.16 • C and 0.77 • C for annual daytime and nighttime temperature respectively. These findings are important to consider for proposed developments of the city as such detail is not currently considered in the urban growth plans for the PMR. The novel intra-urban research approach presented can be applied to other global metropolitan regions to facilitate future transition towards sustainable cities, whereby urban heat impacts can be better managed through optimised land use planning, moving cities towards alignment with the 2030 sustainable development goals and the City Resilience Framework (CRF).

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“…By comparison, others achieved the temporal aggregation through weighting the clearsky LSTs by the QC flags (hereafter termed the unequally weighted aggregation (UWA) strategy) [Zhou et al, 2013;Gawuc and Struzewska, 2016]. This study estimated the weights of the UWA as the inverse-square of the retrieved LST error [Zhou et al, 2013].…”

Section: T T T T T T T T I T T T T T T T Tmentioning

confidence: 99%

“…Dealing with this, different preprocessings of the LST data were adapted in the temporal composition. Some studies disregarded that and directly use the average of the valid LSTs (Zhou et al, 2014); while others, additionally, performed a temporal aggregation of LSTs taking data quality into consideration, such as only using LSTs with good quality (Clinton,2013;Bechtel, 2015;Zhao et al, 2017), or adapting a weighted average method that the LST is weighted by the quality flags provided by the satellite products (i.e., MODIS LST QC flags (Wan, 2008)) (Zhou et al, 2013). Such different data selected methods in temporal aggregation, however, have been clarified to be able to affect the SUHII calculation even for the same city (Gawuc and Struzewska, 2016).…”

Section: Introductionmentioning

confidence: 99%

Does Quality Control Matter? A Revisit of Surface Urban Heat Island Intensity Estimated by Satellite-Derived Land Surface Temperature Products

Lai

Zhan

Huang

2017

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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ABSTRACT:Temporally regular and spatially continuous monitoring of surface urban heat island (SUHI) has been extremely difficult until the advent of spaceborne land surface temperature (LST) products. The higher errors of these LST products compared with in-situ measurements, nevertheless, have resulted in a comparatively inaccuracy and may distort the interpretation of SUHI. Although reports have shown that LST quality matters to the SUHI interpretation, a systematic investigation on how the SUHI indicators are responsive to the LST quality across cities within dissimilar bioclimates remains rare. With regard to this issue, our study chose eighty-six major cities across the mainland China and analyzed the SUHI intensity (SUHII) discrepancies (referred to as ∆SUHII) between using and not using quality control (QC) flags from Moderate Resolution Imaging Spectroradiometer data. Our major findings include: (1) the SUHII can be significantly impacted by the MODIS QC flags, and the associated seasonal ∆SUHIIs generally account for 25.5% (29.6%) of the total intensity in the day (night). (2) The ∆SUHIIs differ season-by-season and significant discrepancies also appear among northern and southern cities, with northern ones often possessing a higher annual mean ∆SUHII. (3) The internal ∆SUHIIs within an individual city are also heterogeneous, with the variations exceeding 5.0 K (3.0 K) in northern (southern) cities. (4) The ∆SUHII is significantly negatively related to the SUHII and cloud cover percentage mostly in transitional seasons. Our findings highlight that one needs to be very careful when using the LST-product-based SUHII to interpret the SUHI.

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Different Patterns in Daytime and Nighttime Thermal Effects of Urbanization in Beijing-Tianjin-Hebei Urban Agglomeration

Cited by 37 publications

References 73 publications

Diversification of Land Surface Temperature Change under Urban Landscape Renewal: A Case Study in the Main City of Shenzhen, China

Diversification of Land Surface Temperature Change under Urban Landscape Renewal: A Case Study in the Main City of Shenzhen, China

Urbanisation-Induced Land Cover Temperature Dynamics for Sustainable Future Urban Heat Island Mitigation

Does Quality Control Matter? A Revisit of Surface Urban Heat Island Intensity Estimated by Satellite-Derived Land Surface Temperature Products

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